| 000 | 01620camuu2200313 a 4500 | |
| 001 | 000000699415 | |
| 005 | 20010328165656 | |
| 008 | 981014s1999 nyua b 001 0 eng | |
| 010 | ▼a 98048578 | |
| 015 | ▼a GB99-49303 | |
| 020 | ▼a 3540636501 (hardcover : acid-free paper) | |
| 040 | ▼a DLC ▼c DLC ▼d OHX ▼d C#P ▼d UKM ▼d PMC ▼d 211009 | |
| 049 | 1 | ▼l 121046815 ▼f 과학 |
| 050 | 0 0 | ▼a TP245.S5 ▼b C39 1999 |
| 072 | 7 | ▼a TP ▼2 lcco |
| 082 | 0 0 | ▼a 660/.2995 ▼2 21 |
| 090 | ▼a 660.2995 ▼b C357w | |
| 245 | 0 0 | ▼a Catalysis and zeolites: ▼b fundamentals and applications / ▼c J. Weitkamp, L. Puppe (eds.). |
| 260 | ▼a New York : ▼b Springer , ▼c 1999. | |
| 300 | ▼a xviii, 564 p. : ▼b ill. ; ▼c 25 cm. | |
| 504 | ▼a Includes bibliographical references and index. | |
| 505 | 0 | ▼a Synthesis of aluminosilicate zeolites and related silica-based materials / Jean-Louis Guth and Henri Kessler -- Phosphate-based zeolites and molecular sieves / Johan A. Martens and Pierre A. Jacobs -- Modification of zeolites / Gunter H. Kuhl -- Characterization of zeolites - infrared and nuclear magnetic resonance spectroscopy and x-ray diffraction / Hellmut G. Karge, Michael Hunger, and Hermann K. Beyer -- Shape-selective catalysis in zeolites / Jens Weitkamp, Stefan Ernst, and Lothar Puppe -- Zeolite effects in organic catalysis / Patrick Espeel... [et al.] -- Zeolites as catalysts in industrial processes / P.M.M. Blauwhoff ... [et al.]. |
| 650 | 0 | ▼a Zeolites. |
| 650 | 0 | ▼a Catalysis. |
| 650 | 4 | ▼a Zeolites. |
| 650 | 4 | ▼a Catalysis. |
| 700 | 1 | ▼a Weitkamp, J. ▼q (Jens) |
| 700 | 1 | ▼a Puppe, L. ▼q (Lothar) ▼d 1943- |
소장정보
| No. | 소장처 | 청구기호 | 등록번호 | 도서상태 | 반납예정일 | 예약 | 서비스 |
|---|---|---|---|---|---|---|---|
| No. 1 | 소장처 과학도서관/Sci-Info(2층서고)/ | 청구기호 660.2995 C357w | 등록번호 121046815 (10회 대출) | 도서상태 대출가능 | 반납예정일 | 예약 | 서비스 |
컨텐츠정보
책소개
Zeolites occur in nature and have been known for almost 250 years as alumino silicate minerals. Examples are clinoptilolite, mordenite, offretite, ferrierite, erionite and chabazite. Today, most of these and many other zeolites are of great interest in heterogeneous catalysis, yet their naturally occurring forms are of limited value as catalysts because nature has not optimized their properties for catalytic applications and the naturally occurring zeolites almost always contain undesired impurity phases. It was only with the advent of synthetic zeolites in the period from about 1948 to 1959 (thanks to the pioneering work of R. M. Barrer and R. M. Milton) that this class of porous materials began to playa role in catalysis. A landmark event was the introduction of synthetic faujasites (zeolite X at first, zeolite Y slightly later) as catalysts in fluid catalytic cracking (FCC) of heavy petroleum distillates in 1962, one of the most important chemical processes with a worldwide capacity of the order of 500 million t/a. Compared to the previously used amorphous silica-alumina catalysts, the zeolites were not only orders of magnitude more active, which enabled drastic process engineering improvements to be made, but they also brought about a significant increase in the yield of the target product, viz. motor gasoline. With the huge FCC capacity worldwide, the added value of this yield enhancement is of the order of 10 billion US $ per year.
Zeolites occur in nature and have been known for almost 250 years as alumino silicate minerals. Examples are clinoptilolite, mordenite, offretite, ferrierite, erionite and chabazite. Today, most of these and many other zeolites are of great interest in heterogeneous catalysis, yet their naturally occurring forms are of limited value as catalysts because nature has not optimized their properties for catalytic applications and the naturally occurring zeolites almost always contain undesired impurity phases. It was only with the advent of synthetic zeolites in the period from about 1948 to 1959 (thanks to the pioneering work of R. M. Barrer and R. M. Milton) that this class of porous materials began to playa role in catalysis. A landmark event was the introduction of synthetic faujasites (zeolite X at first, zeolite Y slightly later) as catalysts in fluid catalytic cracking (FCC) of heavy petroleum distillates in 1962, one of the most important chemical processes with a worldwide capacity of the order of 500 million t/a. Compared to the previously used amorphous silica-alumina catalysts, the zeolites were not only orders of magnitude more active, which enabled drastic process engineering improvements to be made, but they also brought about a significant increase in the yield of the target product, viz. motor gasoline. With the huge FCC capacity worldwide, the added value of this yield enhancement is of the order of 10 billion US $ per year.
New feature
Zeolites and zeolite-like microporous materials have been playing an ever-increasing role in heterogeneous catalysis for more than three decades. An impressive number of large-scale industrial processes in petroleum refining, petrochemistry and the manufacture of organic chemicals are nowadays carried out using zeolite catalysts, and the future of zeolites in industrial catalysis continues to be bright. Authored by an international team of renowned scientists, the seven chapters of this book present a comprehensive overview of the application of zeolites in industrial catalysis, while also providing a true scientific understanding of how zeolites are synthesized, modified and characterized, and providing special emphasis on shape-selective catalysis, which is a unique feature of zeolites.정보제공 :
목차
Synthesis of Aluminosilicate Zeolites and Related Silica-Based Materials.- Phosphate-Based Zeolites and Molecular Sieves.- Modification of Zeolites.- Characterization of Zeolites: Infrared and Nuclear Magnetic Resonance Spectroscopy and X-Ray Diffraction.- Shape-Selective Catalysis in Zeolites.- Zeolite Effects in Organic Catalysis.- Zeolites as Catalysts in Industrial Processes.
정보제공 :